Wilkinson Power Divider Design

// Introduction

What is a Wilkinson Power Divider?

A Wilkinson divider splits one RF signal into two outputs while keeping all three ports matched to Z₀ and the outputs isolated from each other — something a simple T-junction cannot do.

✦ All ports matched to Z₀ — no reflections ✦ Output-to-output isolation — Port 2 and Port 3 cannot see each other ✦ Lossless when balanced — the resistor dissipates zero power during normal operation

Used in: antenna feed networks, PA combiners, phased arrays, test equipment signal splitters.

Beginner tip: Put 10 mW in — each output gets 5 mW (−3 dB). The two quarter-wave arms and one resistor give perfect matching and isolation simultaneously, which a simple wire T-junction cannot do.

// PCB Substrate — enter your board parameters to get exact trace widths & lengths

Dielectric constant εr

Substrate height h (mm)

Copper thickness t (μm)

Loss tangent tan δ

Substrate presets: FR4 (εr=4.4, h=1.6mm, tan δ=0.020) · Rogers 4350B (εr=3.66, h=0.762mm, tan δ=0.0037) · Rogers 5880 (εr=2.2, h=0.787mm, tan δ=0.0009) · RO4003C (εr=3.55, h=0.813mm, tan δ=0.0027)
The Hammerstad-Jensen closed-form model is used — same as our Microstrip Calculator. Accuracy within 1–2% of full-wave EM simulation.

// Select divider type to design

// Equal-Split Wilkinson — Circuit Schematic

Port 1 = Input | Port 2 & Port 3 = Outputs (equal −3 dB each)

// Step 01 — Electrical Design

Frequency, Impedance and Component Values

// Electrical Inputs

Centre frequency f₀MHz

System impedance Z₀Ω

// Electrical Results

Quarter-wave arm impedance Z₁

70.71 Ω

Isolation resistor R

100 Ω

Free-space λ/4 at f₀

31.25 mm

Z₁ = Z₀ × √2 — Each arm acts as a quarter-wave impedance transformer converting the 25 Ω junction (two 50 Ω in parallel) back to 50 Ω at the input.
R = 2 × Z₀ — The isolation resistor absorbs any imbalance between the two outputs and creates port-to-port isolation.

// PCB Trace Dimensions — on your substrate

Trace / Element	Width	Length (λ/4)	Notes
50 Ω port traces	—	—	Feed lines to all 3 ports
70.7 Ω arms (×2)	—	—	Both arms identical
Isolation resistor R	—		0402 chip, between Port 2 & 3 junction

Enter substrate parameters above to see PCB dimensions.

⚡ Verify arm trace in Microstrip Calculator ⚡ Verify 50 Ω trace in Microstrip Calculator

// Step 02 — PCB Layout

Five Layout Rules

① Both arms must be identical in length and shape. Any asymmetry degrades isolation and output balance.

② Place the isolation resistor directly at the output junction. No extra routing between the resistor pads and the trace — use 0402 or 0201.

③ Keep copper pour ≥ 3× trace width away from the arms. Ground fill changes the effective εr and shifts the resonant frequency.

④ Solid continuous ground plane below. No splits or gaps under the divider.

⑤ Add via stitching alongside the arms on multi-layer boards.

Most common mistake: Asymmetric routing of the output traces after the junction. Keep symmetry all the way to the loads or connectors.

// Design Complete

Equal-Split Wilkinson Summary

Frequency

2400MHz

Arm Z₁

70.71Ω

Arm width

—mm

Arm length

—mm

Resistor R

100Ω

Each Output

−3.0dB

// Unequal-Split Wilkinson — Circuit Schematic

Port 2 = more power (K²× Port 3). Both outputs remain matched to Z₀.

// Step 01 — Electrical Design

Specifications, Arm Impedances and Resistor

// Electrical Inputs

Centre frequency f₀MHz

System impedance Z₀Ω

Power ratio K² = P₂/P₃×

K² = 2 → Port 2 twice the power · K² = 3 → 3:1 split · K² = 10 → monitoring tap

// Electrical Results (Pozar formulas)

Z_A — arm to Port 2 (more power)

— Ω

Z_B — arm to Port 3 (less power)

— Ω

Isolation resistor R

— Ω

Power at Port 2

— dB

Power at Port 3

— dB

// PCB Trace Dimensions — on your substrate

Trace / Element	Width	Length (λ/4)	Notes
50 Ω port traces	—	—	Feed lines
Z_A arm (to Port 2)	—	—	More power arm
Z_B arm (to Port 3)	—	—	Less power arm — same length as Z_A
Isolation resistor R	—		0402 chip, nearest E24

Enter substrate parameters above to see PCB dimensions.

⚡ Verify Z_A in Microstrip Calculator ⚡ Verify Z_B in Microstrip Calculator

// Design Complete

Unequal-Split Wilkinson Summary

Frequency

2400MHz

K²

2×

Z_A

—Ω

Z_A width

—mm

Z_B

—Ω

Z_B width

—mm

Resistor R

—Ω

Port 2

—dB

// Wideband Two-Section Wilkinson — Circuit Schematic

Two λ/8 sections per arm with two isolation resistors — ≈doubles bandwidth vs single-section

// Step 01 — Electrical Design

Band Edges, Section Impedances and Resistors

// Electrical Inputs

Lower band edge f₁MHz

Upper band edge f₂MHz

System impedance Z₀Ω

// Electrical Results

Centre frequency f₀ = √(f₁×f₂)

—

Fractional bandwidth

—

Z_s1 = Z₀ × 2^(1/4)

—

Z_s2 = Z₀ × 2^(3/4)

—

R₁ inner = Z₀ × √2

—

R₂ outer = 2×Z₀×√2

—

// PCB Trace Dimensions — on your substrate

Section / Element	Width	Length (λ/8)	Notes
50 Ω port traces	—	—	Feed lines
Z_s1 sections (×2 arms)	—	—	Input section, 4 traces total
Z_s2 sections (×2 arms)	—	—	Output section, 4 traces total
R₁ inner resistors (×2)	—		0402, at mid-section junction
R₂ outer resistors (×2)	—		0402, at output junction

Enter substrate parameters above to see PCB dimensions.

⚡ Verify Z_s1 in Microstrip Calculator ⚡ Verify Z_s2 in Microstrip Calculator

// Design Complete

Wideband Wilkinson Summary

Band

—

Centre f₀

—MHz

Bandwidth

—

Z_s1 width

—mm

Z_s2 width

—mm

Z_s1 length

—mm

R₁

—Ω

R₂

—Ω

Designing Wilkinson Power Dividers